U.S. patent application number 15/175492 was filed with the patent office on 2017-09-07 for graphic structure of touch electrode, touch display panel and touch display device.
The applicant listed for this patent is SHANGHAI TIANMA MICRO-ELECTRONICS CO., LTD., TIANMA MICRO-ELECTRONICS CO., LTD.. Invention is credited to Hong Ding, Liang Liu, Xuening Liu, Qijun Yao.
Application Number | 20170255321 15/175492 |
Document ID | / |
Family ID | 56249794 |
Filed Date | 2017-09-07 |
United States Patent
Application |
20170255321 |
Kind Code |
A1 |
Ding; Hong ; et al. |
September 7, 2017 |
GRAPHIC STRUCTURE OF TOUCH ELECTRODE, TOUCH DISPLAY PANEL AND TOUCH
DISPLAY DEVICE
Abstract
A graphic structure of a touch electrode is provided, and the
graphic structure of a touch electrode a plurality of touch
electrode assemblies which are arranged in an array mode and at
least one of which is mutually fit with and insulated from the
adjacent touch electrode assembly. The touch electrode assembly
comprises at least one first touch electrode and at least one
second touch electrode, and the first touch electrodes and the
second touch electrodes are insulated from each other; the ratio of
widths of any first touch electrode and any second touch electrode
in the first direction is in the range of 0.9-1.12, thereby solving
the issue of graphic visibility when a touch display panel with
mutually fit touch electrodes displays an image. Further, the touch
display panel and a touch display device disclosure also have the
characteristic of high touch sensitivity, so that a user has a
better touch experience.
Inventors: |
Ding; Hong; (Shanghai,
CN) ; Yao; Qijun; (Shanghai, CN) ; Liu;
Liang; (Shanghai, CN) ; Liu; Xuening;
(Shanghai, CN) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
SHANGHAI TIANMA MICRO-ELECTRONICS CO., LTD.
TIANMA MICRO-ELECTRONICS CO., LTD. |
Shanghai
Shenzhen |
|
CN
CN |
|
|
Family ID: |
56249794 |
Appl. No.: |
15/175492 |
Filed: |
June 7, 2016 |
Current U.S.
Class: |
1/1 |
Current CPC
Class: |
G06F 3/0412 20130101;
G06F 3/04166 20190501; G06F 3/044 20130101; G06F 3/0416 20130101;
G06F 2203/04111 20130101; G06F 2203/04103 20130101 |
International
Class: |
G06F 3/041 20060101
G06F003/041; G06F 3/044 20060101 G06F003/044 |
Foreign Application Data
Date |
Code |
Application Number |
Mar 1, 2016 |
CN |
201610115282.9 |
Claims
1. A graphic structure of a touch electrode, comprising a plurality
of touch electrode assemblies, wherein the plurality of touch
electrode assemblies are arranged in an array mode, and at least
one of the plurality of touch electrode assemblies is mutually fit
with and insulated from an adjacent touch electrode assembly; one
of the plurality of touch electrode assemblies comprises at least
one first touch electrode and at least one second touch electrode,
and the first touch electrodes and the second touch electrodes are
insulated from each other; one of the at least one first touch
electrode has a plurality of first effective widths in a second
direction, and a ratio between two of the plurality of first
effective widths of the first touch electrode along the first
direction is a1, wherein, 0.9.ltoreq.a1.ltoreq.1.12; one of the at
least one second touch electrode has a plurality of second
effective widths in the second direction, and the ratio between any
two second effective widths of a second touch electrode along the
first direction is a2, wherein, 0.9.ltoreq.a2.ltoreq.1.12; and the
ratio between any the first effective width and any the second
effective width is b, wherein, 0.9.ltoreq.b.ltoreq.1.12.
2. A graphic structure of a touch electrode according to claim 1,
wherein, the first touch electrode comprises a plurality of first
touch sub-electrodes which are electrically connected and are
rectangular electrodes; and/or the second touch electrode comprises
a plurality of second touch sub-electrodes which are electrically
connected and are rectangular electrodes.
3. A graphic structure of a touch electrode according to claim 2,
wherein, one of the touch electrode assemblies comprises one first
touch electrode and one second touch electrode, wherein the first
touch electrode comprises six first touch sub-electrodes: a first
touch sub-electrode 1, a first touch sub-electrode 2, a first touch
sub-electrode 3, a first touch sub-electrode 4, a first touch
sub-electrode 5 and a first touch sub-electrode 6; the second touch
electrode comprises six second touch sub-electrodes: a second touch
sub-electrode 1, a second touch sub-electrode 2, a second touch
sub-electrode 3, a second touch sub-electrode 4, a second touch
sub-electrode 5 and a second touch sub-electrode 6; for one of the
plurality of touch electrode assemblies, the first touch
sub-electrode 1 and the first touch sub-electrode 6 are orderly
arranged in the first line 1L in the first direction, the first
touch sub-electrode 2 and the first touch sub-electrode 3 are
orderly arranged in the second line 2L in the first direction, the
second touch sub-electrode 4, the second touch sub-electrode 5, the
first touch sub-electrode 4 and the first touch sub-electrode 5 are
orderly arranged in the third line 3L in the first direction, the
second touch sub-electrode 2 and the second touch sub-electrode 3
are orderly arranged in the fourth line 4L in the first direction,
and the second touch sub-electrode 1 and the second touch
sub-electrode 6 are orderly arranged in the fifth line 5L in the
first direction; and for one of touch electrode assembly, the
second touch sub-electrode 4 is arranged in the first row 1R in the
second direction, the first touch sub-electrode 2 and the second
touch sub-electrode 2 are orderly arranged in the second row in the
second direction, the first touch sub-electrode 1, the second touch
sub-electrode 5 and the second touch sub-electrode 1 are orderly
arranged in the third row 3R in the second direction, the first
touch electrode 6, the first touch sub-electrode 4 and the second
touch sub-electrode 6 are orderly arranged in the fourth row 4R in
the second direction, the first touch sub-electrode 3 and the
second touch sub-electrode 3 are orderly arranged in the fifth row
5R in the second direction, and the first touch sub-electrode 5 is
arranged in the sixth row 6R in the second direction; where the
first touch sub-electrode 1 and the first touch sub-electrode 6 are
an integrated structure, and the second touch sub-electrode 1 and
the second touch sub-electrode 6 are an integrated structure.
4. A graphic structure of a touch electrode according to claim 3,
wherein, lengths of each of the six first touch sub-electrodes and
each of the six second touch sub-electrodes in the first direction
and lengths of the first touch sub-electrode 1, the first touch
sub-electrode 2, the first touch sub-electrode 3, the first touch
sub-electrode 6, the second touch sub-electrode 1, the second touch
sub-electrode 2, the second touch sub-electrode 3 and the second
touch sub-electrode 6 in the second direction are in the range of
0.75 mm-1.625 mm; the lengths of the first touch sub-electrode 4,
the first touch sub-electrode 5, the second touch sub-electrode 4
and the second touch sub-electrode 5 in the second direction are in
the range of 1.5 mm-3.25 mm.
5. A graphic structure of a touch electrode according to claim 3,
wherein, a length of each of the six touch sub-electrodes in the
first direction is equal to a length of each of the six second
touch sub-electrode in the first direction; lengths of the first
touch sub-electrode 4, the first touch sub-electrode 5, the second
touch sub-electrode 4 and the second touch sub-electrode 5 in the
second direction are equal; the lengths of the first touch
sub-electrode 1, the first touch sub-electrode 2, the first touch
sub-electrode 3, the first touch sub-electrode 6, the second touch
sub-electrode 1, the second touch sub-electrode 2, the second touch
sub-electrode 3 as well as the second touch sub-electrode 6 in the
second direction are equal; the lengths of the first touch
sub-electrode 4, the first touch sub-electrode 5, the second touch
sub-electrode 4 and the second touch sub-electrode 5 in the second
direction are twice the lengths of the first touch sub-electrode 1,
the first touch sub-electrode 2, the first touch sub-electrode 3,
the first touch sub-electrode 6, the second touch sub-electrode 1,
the second touch sub-electrode 2, the second touch sub-electrode 3
and the second touch sub-electrode 6 in the second direction.
6. A graphic structure of a touch electrode according to claim 5,
wherein, one of the plurality of touch electrode assemblies and
four adjacent touch electrode assemblies are encircled and fit with
each other to form a touch electrode assembly group.
7. A graphic structure of a touch electrode according to claim 6,
wherein, the touch electrode assembly group is in turn in the first
direction a first touch electrode assembly, a second touch
electrode assembly and a third touch electrode assembly; the touch
electrode assembly group in in turn in the second direction a
fourth touch electrode assembly, a second touch electrode assembly
and a fifth touch electrode assembly.
8. A graphic structure of a touch electrode according to claim 7,
wherein, a first touch electrode 5 of the first touch electrode
assembly is positioned in a region encircled by the first touch
sub-electrode 2, the second touch sub-electrode 2, the second touch
sub-electrode 4 and the second touch sub-electrode 5 of the second
touch electrode assembly; a second touch sub-electrode 4 of the
third touch electrode assembly is positioned in a region encircled
by the first touch sub-electrode 3, the first touch sub-electrode
4, the first touch sub-electrode 5 and the second touch
sub-electrode 3 of the second touch electrode assembly; a second
touch sub-electrode 1 of the fourth touch electrode assembly is
positioned in an area encircled by the first touch sub-electrode 1,
the first touch sub-electrode 6, the first touch sub-electrode 2,
the first touch sub-electrode 3, the first touch sub-electrode 4
and the second touch sub-electrode 5 of the second touch electrode
assembly; a first touch sub-electrode 1 of the fifth touch
electrode assembly is positioned in an area encircled by the second
touch sub-electrode 1, the second touch sub-electrode 2, the second
touch sub-electrode 3, the second touch sub-electrode 5 and the
first touch sub-electrode 4 of the second touch electrode
assembly.
9. A graphic structure of a touch electrode according to claim 1,
wherein, each of the plurality of touch electrode assemblies
comprises two first touch electrodes and two second touch
electrodes, and is positioned in a checkerboard lattice with
eight-line and eight-row, and the checkerboard lattice comprises 64
sublattices; the two first touch electrodes each comprise four
first touch sub-electrodes: a first touch sub-electrode 1, a first
touch sub-electrode 2, a first touch sub-electrode 3 and a first
touch sub-electrode 4; the two second touch electrodes each
comprise four second touch sub-electrodes: a second touch
sub-electrode 1, a second touch sub-electrode 2, a second touch
sub-electrode 3 and a second touch sub-electrode 4; the first touch
sub-electrode 1 of one of the first touch electrodes takes up a
second line and second row sublattice, a second line and third row
sublattice, a third line and third row sublattice and a third line
and fourth row sublattice of the checkerboard lattice; the first
touch sub-electrode 2 takes up a fourth line and first row
sublattice and a fourth line and second row sublattice of the
checkerboard lattice; the first touch sub-electrode 3 takes up a
fifth line and third row sublattice and a fifth line and fourth row
sublattice of the checkerboard lattice; the first touch
sub-electrode 4 takes up a sixth line and first row sublattice and
a sixth line and second row sublattice of the checkerboard lattice;
the second touch sub-electrode 1 of one of the second touch
electrodes takes up a first line and third row sublattice of the
checkerboard lattice; the second touch sub-electrode 2 takes up a
first line and fifth row sublattice, a second line and fifth row
sublattice, a third line and fifth row sublattice and a third line
and sixth row sublattice of the checkerboard lattice; the second
touch sub-electrode 3 takes up a second line and seventh row
sublattice of the checkerboard lattice; the second touch
sub-electrode 4 takes up a fourth line and third row sublattice and
a fourth line and fourth row sublattice of the checkerboard
lattice; the two first touch electrodes are centrally symmetrical
with respect to a central point of the checkerboard lattice; the
two second touch electrodes are centrally symmetrical with respect
to the central point of the checkerboard lattice; and the line
direction of the checkerboard lattice is the first direction, and
the row direction of the checkerboard lattice is the second
direction.
10. A graphic structure of a touch electrode according to claim 9,
wherein, the two second touch electrodes are electrically
connected.
11. A graphic structure of a touch electrode according to claim 10,
wherein, the sublattices of the checkerboard lattice each is a
square with the equal side length.
12. A graphic structure of a touch electrode according to claim 11,
wherein, one of the plurality of touch electrode assemblies and
four adjacent touch electrode assemblies are fit with each other in
a concave-convex fit mode.
13. A touch display panel comprising the graphic structure of the
touch electrode according to claim 1, wherein the touch display
panel further comprises: a plurality of gate lines for transmitting
drive scanning signals for a film transistor; the first direction
is the same as an extension direction of the gate lines; the second
direction is perpendicular to the first direction; and the touch
electrode assemblies act as touch electrodes at a touch phase, and
act as common electrodes at a display phase, wherein the common
electrodes provide common signals for display pixels.
14. The touch display panel according to claim 13, further
comprising an insulation layer positioned at one side of the touch
electrode assembly; a touch metal layer, the insulation layer is
positioned between the touch metal layer and the touch electrode
assembly; and the touch metal layer comprises a plurality of touch
signal lines, each of the at least one first touch electrode is
electrically connected with at least one of the touch signal lines;
each of the at least one second touch electrode is electrically
connected with at least one of the touch signal lines, the touch
signal lines are adapted for transmitting touch signals for the
first touch electrodes and the second touch electrodes.
15. The touch display panel according to claim 14, wherein, the
touch metal layer further comprises a touch electrode connecting
line; the touch electrode connecting line is adapted for
electrically connecting a plurality of first touch sub-electrodes
of one of the at least one first touch electrode and electrically
connecting a plurality of second touch sub-electrodes of one of the
at least one second touch electrode.
16. The touch display panel according to claim 14 or claim 15,
wherein, the insulation layer is provided with a plurality of
through holes; and the touch signal lines are electrically
connected with the at least one first touch electrode and with the
at least one second touch electrode via the through holes; or the
touch electrode connecting line is adapted for electrically
connecting a plurality of first touch sub-electrodes of one of the
at least one first touch electrode and electrically connecting a
plurality of second touch sub-electrodes of one of the at least one
second touch electrode via the through holes.
17. The touch display panel according to claim 18, wherein, the
plurality of first touch sub-electrodes of one of the at least one
first touch electrode are electrically connected with common
electrodes; and/or the plurality of touch sub-electrodes of one of
the at least one second touch electrodes are electrically connected
via the common electrodes.
18. A touch display device, comprising a touch display panel
according to the claim 1.
Description
TECHNICAL FIELD
[0001] The disclosure relates to the field of display, and in
particular, to a graphic structure of a touch electrode, a touch
display panel and a touch display device.
BACKGROUND
[0002] As an input medium, a touch screen is the most simple,
convenient and natural human-computer interaction mode at present.
It has become a research and development hot spots of more and more
flat-panel display manufacturers that a touch function is
integrated on the display device.
[0003] A capacitive touch is a widely used touch technique at
present. In order to reduce the thickness of a display panel and
achieve the touch function, a touch structure is generally
integrated into the display panel. A plurality of touch electrodes
are formed in a display area. The touch electrode can be
multiplexed with common electrodes of display pixels and driven in
a time division mode. At the display phase, the common electrodes
receive common signals, and at the touch phase, the common
electrodes receive touch signals. In the related art, in order to
enhance the touch sensitivity, the touch electrodes can be set as
mutually fit irregular graphics, although this type of design
enhances the touch sensitivity, while brings the issue of
visibility when images of the graphics of the touch electrodes are
displayed, so that the display performance of the touch display
panel is reduced greatly.
SUMMARY
[0004] In light of the above problems in the related art,
embodiments provide a graphic structure of the touch electrode, a
touch display panel and a touch display device.
[0005] One aspect of the disclosure provides a graphic structure of
the touch electrode comprising a plurality of touch electrode
assemblies, which are arranged in an array mode and at least one of
which mutually fit with and insulated from the adjacent touch
electrode assembly.
[0006] The touch electrode assembly comprises at least one first
touch electrode and at least one second touch electrode, and the
first touch electrodes and the second touch electrodes are
insulated from each other.
[0007] Any the first touch electrode has a plurality of first
effective widths in the second direction, and the ratio between any
two first effective widths of the first touch electrode along the
first direction is a1, wherein, 0.9.ltoreq.a1.ltoreq.1.12.
[0008] Any the second touch electrode has a plurality of second
effective widths in the second direction, and the ratio between any
two second effective widths of the second touch electrode along the
first direction is a2, wherein, 0.9.ltoreq.a2.ltoreq.1.12. The
ratio between any the first effective width and any the second
effective width is b, wherein, 0.9.ltoreq.b.ltoreq.1.12;
[0009] Another aspect of embodiments also provides a touch display
panel comprising the graphic structure of the touch electrode.
[0010] Another aspect of embodiments also provides a touch display
device comprising the touch display panel.
[0011] The graphic structure of the touch electrode, the touch
display panel and the touch display device, which are adopted by
the disclosure, have the following advantages:
[0012] The ratio of any two first effective widths of the first
touch electrodes in the second direction, the ratio of any two
second effective widths of the second touch electrodes in the
second direction, as well as the ratio of any first effective width
and any second effective width are set in the range of 0.9-1.12, so
that the first touch electrodes and the second touch electrodes
have uniform electrode effective widths in the second direction,
thereby solving the issue of visibility when an image of the touch
display panel is displayed; moreover, the touch display panel and
the touch display device of the disclosure also have the high touch
sensitivity, so that a user has a better touch experience.
DESCRIPTION OF DRAWINGS
[0013] FIG. 1a is a schematic diagram of a graphic structure of a
touch electrode according to an embodiment of the disclosure;
[0014] FIG. 1b is a schematic diagram of a first mutually fit mode
of a plurality of touch electrode assemblies according to the
embodiment of the disclosure;
[0015] FIG. 1c is a schematic diagram of a second mutually fit mode
of the plurality of touch electrode assemblies according to the
embodiment of the disclosure;
[0016] FIG. 2a is a schematic diagram of a touch electrode assembly
according to the embodiment of the disclosure;
[0017] FIG. 2b is a schematic diagram of first effective widths and
second effective widths according to the embodiment of the
disclosure;
[0018] FIG. 3 is a schematic diagram of an arrangement of a
plurality of first touch sub-electrodes and a plurality of second
touch sub-electrodes of the touch electrode assembly according to
the embodiment of the disclosure;
[0019] FIG. 4a is a schematic diagram of a touch electrode assembly
group according to the embodiment of the disclosure;
[0020] FIG. 4b of a partial schematic diagram of the touch
electrode assembly group according to the embodiment of the
disclosure;
[0021] FIG. 5a is a schematic diagram of a graphic structure of a
touch electrode according to another embodiment of the
disclosure;
[0022] FIG. 5b is a schematic diagram of a checkerboard lattice
according to the embodiment of the disclosure;
[0023] FIG. 6 is a schematic diagram of the mutual concave-convex
fit mode of a plurality of touch electrode assemblies according to
the embodiment of the disclosure;
[0024] FIG. 7a is a schematic diagram of a touch display panel
according to further another embodiment of the disclosure;
[0025] FIG. 7b is a sectional diagram taken along AA' in FIG.
7a;
[0026] FIG. 8a is a schematic diagram of a connection of a touch
electrode assembly according to the embodiment of the
disclosure;
[0027] FIG. 8b is a sectional diagram taken along CC' in FIG.
8a;
[0028] FIG. 9a is a schematic diagram of a connection of two touch
electrode assemblies at the mutually fit part according to the
embodiment of the disclosure;
[0029] FIG. 9b is a partial amplified schematic diagram of FIG. 9a
at the part C;
[0030] FIG. 9c is a sectional diagram taken along DD' in FIG.
9b;
[0031] FIG. 9d is a sectional diagram taken along EE' in FIG.
9b.
DETAILED DESCRIPTION OF THE EMBODIMENTS
[0032] The disclosure is further described in detail in conjunction
with accompanying drawings and embodiments. It should be understood
that the particular embodiments described herein are only used for
explaining the relevant disclosure, rather than limiting the
disclosure. In addition, it also should be noted that parts
relevant to the disclosure are only shown in the accompanying
drawings for the convenience of description.
[0033] It should be noted that the embodiments in the disclosure
and features in the embodiments can be combined with each other
under the condition of no conflict. The disclosure will be
described in detail hereinafter with reference to the accompanying
drawings.
[0034] FIG. 1a is a schematic structure of a graphic structure of a
touch electrode according to one embodiment. FIG. 1b is a schematic
diagram of a first mutually fit mode of a plurality of touch
electrode assemblies according to the embodiment. FIG. 1c is a
schematic diagram of a second mutually fit mode of the plurality of
touch electrode assemblies according to the embodiment. FIG. 2a is
a schematic diagram of a touch electrode assembly according to the
embodiment. FIG. 2b is a schematic diagram of first effective
widths and second effective widths according to the embodiment.
[0035] Referring to FIG. 1a, the graphic structure of the touch
electrode comprises a plurality of touch electrode assemblies 100,
which are arranged in an array mode and at least one of which
mutually fit with and insulated from the adjacent touch electrode
assemblies 100'.
[0036] The plurality of touch electrode assemblies 100 are arranged
in an array mode, and at least one of first touch electrode
assemblies 100 mutually fit with the adjacent touch electrode
assemblies 100'.
[0037] As shown in FIG. 1b, the first mutually fit mode is that
partial area of a touch electrode assembly A can be completely
encircled by the other touch electrode assembly B, and the mutually
fit mode is called as mutually encircled fit. As shown in FIG. 1c,
the second mutually fit mode is that a convex part of a touch
electrode assembly A is positioned within a concave part of the
other touch electrode assembly B, and the mutually fit mode is
called as the mutually concave-convex fit. The mutually fit between
the touch electrode assemblies enable each touch electrode assembly
to be distributed more uniformly, so that the touch electrode
assemblies have larger mutual capacitance effective areas, and the
touch precision and sensitivity are enhanced. According to the
description below of the embodiment, the embodiment provides
graphic structures of a touch electrode of the touch electrode
assembly with the first mutually fit mode. The other embodiments
also provide the graphic structures of the touch electrodes of the
touch electrode assemblies with the second mutually fit mode.
[0038] Continue to refer to FIG. 2a and FIG. 2b, the touch
electrode assembly 100 comprises at least one first touch electrode
101 and at least one second touch electrode 102 which are insulated
from each other.
[0039] Any first touch electrode 101 has a plurality of first
effective widths in the second direction, and the ratio between any
two first effective widths of a first touch electrode 101 along the
first direction is a1, wherein, 0.9.ltoreq.a1.ltoreq.1.12.
[0040] Any second touch electrode 102 has a plurality of second
effective widths in the second direction, and the ratio between any
two second effective widths of a second touch electrode along the
first direction is a2, wherein, 0.9.ltoreq.a2.ltoreq.1.12.
[0041] The ratio between any first effective width and any second
effective width is b, wherein, 0.9.ltoreq.b.ltoreq.1.12.
[0042] In one embodiment, a touch electrode assembly comprises at
least one first touch electrode 101 and at least one second touch
electrode 102 which are insulated from each other. The
differentiation of the touch electrode assemblies in the embodiment
directs to well describe the graphic structures of the touch
electrodes provided by the embodiment, and is not functional
differentiation, and the first touch electrode and the second touch
electrode in one touch electrode assembly are respectively
individual touch electrodes. The graphic structures of the touch
electrodes can be obtained by an array arrangement of a touch
electrode assembly in the first direction and in the second
direction.
[0043] Any first touch electrode 101 has a plurality of first
effective widths in the second direction, and the ratio between any
two first effective widths of the first touch electrode 101 along
the first direction is a1, wherein, 0.9.ltoreq.a1.ltoreq.1.12. The
definition of the first effective width sees FIG. 2b. The first
touch electrode 101 has a plurality of first effective widths in
the second direction, and three first effective widths are listed
herein: D11, D12 and D13 which are substantial widths of the first
touch electrode along the first direction, for example, the first
effective width D12 is the sum of the width D12a and D12b along the
first direction, and the first effective width D13 is the sum of
the width D13a and D13b along the first direction.
[0044] Similarly, the second touch electrode 102 has a plurality of
second effective widths in the second direction. Three second
effective widths are listed herein: D21, D22 and D23 which are
substantial widths of the second touch electrode along the first
direction, for instance, the second effective width D21 is the sum
of the widths D21a and D21b along the first direction, and the
second effective width D22 is the sum of the widths D22a and D22b
along the first direction.
[0045] It should be understood that the numbers of the first
effective widths and the second effective widths theoretically can
be infinite, and the ratio between any two first effective widths
is a1, wherein 0.9.ltoreq.a1.ltoreq.1.12. The ratio between any two
second effective widths is a2, wherein, 0.9.ltoreq.a2.ltoreq.1.12;
and the ratio between any the first effective width and any the
second effective width is b, wherein, 0.9.ltoreq.b.ltoreq.1.12.
[0046] According to the embodiment, the effective widths of each
first touch electrode and each second touch electrode along the
first direction are approximately equal, so that when an image is
displayed, influences of display signals on each first touch
electrode and each second touch electrode are basically consistent.
Therefore the issue that graphics of mutually fit touch electrode
assemblies are visible when being displayed can be solved.
Moreover, the graphic structure of the touch electrode provided by
the embodiment enable each touch electrode assembly to have more
uniform distribution due to the mutually fit of each touch
electrode assembly, so that each touch electrode assembly has a
larger capacitive effective area, the touch precision and
sensitivity can be enhanced, and pen touch can be supported
better.
[0047] Alternatively, continue to refer to FIG. 2a, the touch
electrode assembly 100 comprises a first touch electrode 101 and a
second touch electrode 102 which are equal in shape and size. In
one embodiment, one touch electrode assembly 100 consists of a
first touch electrode 101 and a second touch electrode 102, and the
first touch electrode and the second touch electrode are configured
to be with the same shape and size. Thus, on the one hand, the
manufacturing technology of the touch electrode can be simplified,
and on the other hand, each first touch electrode 101 and each
second touch electrode 102 have more uniform electrode arrangement
modes. It can be seen from FIG. 2a, the second touch electrode 102
can be a graphic structure obtained by rotating the first touch
electrode 101 180 degrees about point O.
[0048] Alternatively, the first touch electrode comprises a
plurality of first touch sub-electrodes which are electrically
connected each other and are rectangular electrodes; and/or
[0049] The second touch electrode comprises a plurality of second
touch sub-electrodes which are electrically connected each other
and are rectangular electrodes.
[0050] In order to achieve the graphic structures of touch
electrodes of the touch electrode assembly with the first mutually
fit mode in the embodiment, the first touch electrode can comprise
a plurality of first touch sub-electrodes which are electrically
connected each other. It should be understood that, under the
condition that the plurality of first touch sub-electrodes are
combined with each other to form the first touch electrode, any two
of the plurality of touch electrode assemblies can be freely fit
via the first mutually fit mode, so that the plurality of touch
electrode assemblies can be arranged more freely and uniformly,
thereby enhancing the touch sensitivity. Alternatively, in the
embodiment, the plurality of touch sub-electrodes can be
rectangular electrodes, and the mutual combination among the
rectangular electrodes is simpler, and the difficulty of electrode
manufacturing technology can be lowered.
[0051] Alternatively, the second touch sub-electrodes can be
electrodes integrally formed which have the same shape and size as
the first touch sub-electrodes, and also can have a plurality of
the second touch sub-electrodes connected electrically, and we will
not describe in detail.
[0052] Alternatively, FIG. 3 is the schematic diagram of an
arrangement of a plurality of first touch sub-electrodes and a
plurality of second touch sub-electrodes of a touch electrode
assembly provided by the embodiment. As shown in FIG. 3, the first
touch electrode comprises six first touch sub-electrodes: the first
touch sub-electrode 1 T11, the first touch sub-electrode 2 T12, the
first touch sub-electrode 3 T13, a first touch sub-electrode 4 T14,
a first touch sub-electrode 5 T15 and a first touch sub-electrode 6
T16.
[0053] The second touch electrode comprises six second touch
sub-electrodes: the second touch sub-electrode 1 T21, the second
touch sub-electrode 2 T22, the second touch sub-electrode 3 T23,
the second touch sub-electrode 4 T24, the second touch
sub-electrode 5 T25 and the second touch sub-electrode 6 T26.
[0054] For any touch electrode assembly, the first touch
sub-electrode 1 T11 and the first touch sub-electrode 6 T16 are
orderly arranged in the first line 1L in the first direction, the
first touch sub-electrode 2 T12 and the first touch sub-electrode 3
T13 are orderly arranged in the second line 2L in the first
direction, the second touch sub-electrode 6 T26, the second touch
sub-electrode 5 T25, the first touch sub-electrode 4 T14 and the
first touch sub-electrode 5 T15 are orderly arranged in the third
line 3L in the first direction, the second touch sub-electrode 2
T22 and the second touch sub-electrode 3 T23 are orderly arranged
in the fourth line 4L in the first direction, and the second touch
sub-electrode 1 T21 and the second touch sub-electrode 6 T26 are
orderly arranged in the fifth line 5L in the first direction.
[0055] For any touch electrode assembly, the second touch
sub-electrode 4 T24 is arranged in the first row 1R in the second
direction. The first touch sub-electrode 2 T12 and the second touch
sub-electrode 2 T22 are orderly arranged in the second row in the
second direction, the first touch sub-electrode 1 T11. The second
touch sub-electrode 5 T25 and the second touch sub-electrode 1 T21
are orderly arranged in the third row 3R in the second direction.
The first touch electrode 6 T16, the first touch sub-electrode 4
T14 and the second touch sub-electrode 6 T26 are orderly arranged
in the fourth row 4R in the second direction. The first touch
sub-electrode 3 T13 and the second touch sub-electrode 3 T23 are
orderly arranged in the fifth row 5R in the second direction, and
the first touch sub-electrode 5 T25 is arranged in the sixth row 6R
in the second direction;
[0056] The first touch sub-electrode 1 T11 and the first touch
sub-electrode 6 T16 are an integrated structure, and the second
touch sub-electrode 1 T21 and the second touch sub-electrode 6 T26
are an integrated structure.
[0057] According to the graphic structure of the touch electrode
provided by the embodiment, the touch electrode assembly formed by
arranging a plurality of first touch sub-electrodes of the first
touch electrode and a plurality of second touch sub-electrodes of
the second touch electrode in a specific mode is an axial
symmetrical graphic structure and has different symmetrical axes in
various directions. Thus, the graphic structure of the touch
electrode can guarantee that the touch at each direction has the
same sensitivity. Moreover, in one touch electrode assembly, the
ratio of each first effective width and the ratio of each second
effective width of the first touch electrode and the second touch
electrode in the first direction, and the ratio of any first
effective width and any second effective width are approximately
equal, so that the issue of graphic visibility of the touch
electrode assembly cannot be occurred when the touch electrode
assembly displays an image. Therefore, the good display effect is
ensured, and the touch electrode assembly has very high touch
sensitivity.
[0058] In the embodiment, the first touch sub-electrode 1 T11 and
the first touch sub-electrode 6 T16 are an integrated structure;
the second touch sub-electrode 1 T21 and the second touch
sub-electrode 6 T26 are an integrated structure. The integrated
structure means that the first touch sub-electrode 1 T11 and the
first touch sub-electrode 6 T16 can be an electrode formed
integrally, and the second touch sub-electrode 1 T21 and the second
touch sub-electrode 6 T26 can be an electrode formed integrally.
According to the embodiment, under the condition of the first
mutually fit mode, an integral structure can be adopted by a
plurality of first touch sub-electrodes or a plurality of second
touch sub-electrodes, thereby simplifying the technology
manufacturing.
[0059] Alternatively, continue to refer to FIG. 3, the length of
each first touch sub-electrode of the first touch electrodes and
each second touch sub-electrode of the second touch electrodes in
the first direction and the length of the first touch sub-electrode
1 T11, the first touch sub-electrode 2 T12, the first touch
sub-electrode 3 T13, the first touch sub-electrode 6 T16, the
second touch sub-electrode 1 T21, the second touch sub-electrode 2
T22, the second touch sub-electrode 3 T23 and the second touch
sub-electrode 6 T26 in the second direction are in the range of
0.75 mm-1.625 mm.
[0060] The length of the first touch sub-electrode 4 T14, the first
touch sub-electrode 5 T15, the second touch sub-electrode 4 T24 and
the second touch sub-electrode 5 T25 in the second direction are in
the range of 1.5 mm-3.25 mm.
[0061] When the widths of each first touch sub-electrode and each
second touch sub-electrode in the first direction and in the second
direction meet the value conditions, the favorable touch
sensitivity can be obtained, technological difficulty for
manufacturing the touch electrode cannot caused, and the pen touch
of 1.0 mm-2.5 mm can be supported better.
[0062] Alternatively, the length of each first touch sub-electrode
of the first touch electrode in the first direction is equal to the
length of each second touch sub-electrode of the second touch
electrode in the first direction.
[0063] The lengths of the first touch sub-electrode 4 T14, the
first touch sub-electrode 5 T15, the second touch sub-electrode 4
T24 and the second touch sub-electrode 5 T25 in the second
direction are equal.
[0064] The first touch sub-electrode 1 T11, the first touch
sub-electrode 2 T12, the first touch sub-electrode 3 T13, the first
touch sub-electrode 6 T16, the second touch sub-electrode 1 T21,
the second touch sub-electrode 2 T22, the second touch
sub-electrode 3 T23 as well as the second touch sub-electrode 6 T26
in the second direction are equal.
[0065] The lengths of the first touch sub-electrode 4 T14, the
first touch sub-electrode 5 T15, the second touch sub-electrode 4
T24 and the second touch sub-electrode 5 T25 in the second
direction are twice the lengths of the first touch sub-electrode 1
T11, the first touch sub-electrode 2 T12, the first touch
sub-electrode 3 T13, the first touch sub-electrode 6 T16, the
second touch sub-electrode 1 T21, the second touch sub-electrode 2
T22, the second touch sub-electrode 3 T23 and the second touch
sub-electrode 6 T26 in the second direction.
[0066] When the widths of each first touch sub-electrode and each
second touch sub-electrode in the first direction and in the second
direction meet the proportional condition, each touch electrode
assembly can be fit better, and each touch electrode assembly can
have the largest touch electrode area besides the necessary
insulation distance among them, thereby enhancing the touch
sensitivity.
[0067] FIG. 4a is a schematic diagram of a touch electrode assembly
group according to the embodiment. FIG. 4b is a partial schematic
diagram of the touch electrode assembly group according to the
embodiment. As shown in FIG. 4a, one touch electrode assembly and
four adjacent touch electrode assemblies are fit with each other to
form a touch electrode assembly group 40.
[0068] The touch electrode assembly group 40 is in turn in the
first direction: a first touch electrode assembly 400a, a second
touch electrode assembly 400 and a third touch electrode assembly
400c.
[0069] The touch electrode assembly group 40 is in turn in the
second direction: a fourth touch assembly 400b, a second touch
electrode assembly 400 and a fifth touch electrode assembly
400d.
[0070] The touch electrode assembly 400 mutually fit with its two
adjacent touch electrode assemblies 400a and 400c in the first
direction, and mutually fit with its two adjacent touch electrodes
400b and 400d in the second direction. It can be understood by a
person skilled in the art that each touch electrode assembly can
fit with the adjacent touch electrode assemblies in the graphic
structure of the touch electrode assembly provided by the
embodiment, so as to form a tight arrangement structure of the
touch electrode assemblies.
[0071] Moreover, as shown in FIG. 4b, the first touch electrode 401
in the touch electrode assembly 400 is simultaneously mutually fit
with both of the second touch electrode 402b of the adjacent touch
electrode assembly 400b and the second touch electrode 402c of the
adjacent touch electrode assembly 400c. It should be noted that in
order to show the above fit relation more clearly, the first touch
electrode of the touch electrode assembly 400b and the first touch
electrode of the touch electrode assembly 400c are omitted in FIG.
4b.
[0072] Similarly, the second touch electrode in the touch electrode
assembly 400 is also simultaneously mutually fit with the first
touch electrodes of the other two adjacent touch electrode
assemblies. Because the first touch electrode and the second touch
electrode in one touch electrode assembly 400 are insulated from
each other, the first touch electrode and the second touch
electrode of the touch electrode assembly 400 respectively mutually
fit with the first touch electrode and the second touch electrode
of the adjacent touch electrode assembly, so as to guarantee that
all the electrically independent touch electrodes can mutually fit
with the adjacent touch electrodes in the graphic structure of the
whole touch electrode. The distribution area of the touch
electrodes is enhanced maximally, so that the touch sensitivity is
enhanced maximally. Moreover, the ratio of each first effective
width, the ratio of each second effective width as well as any
first effective width and any second effective width of the first
touch electrodes and second touch electrodes along the first
direction are approximately equal, so that the visible issue of the
graphics of the touch electrode assemblies cannot be occurred when
the touch electrode assemblies display images, thereby ensuring the
good display effect.
[0073] FIG. 5a is a schematic diagram of a graphic structure of a
touch electrode according to another embodiment. FIG. 5b is a
schematic diagram of a checkerboard lattice in the embodiment. As
shown in FIG. 5a and FIG. 5b, a touch electrode assembly 500
comprises two first touch electrodes 501 and two second touch
electrodes 502. The touch electrode assembly 500 is positioned in a
checkerboard lattice S with eight-line and eight-row, and the
checkerboard lattice comprises 64 sublattices.
[0074] The first touch electrode each comprises four first touch
sub-electrodes: a first touch sub-electrode 1 T11, a first touch
sub-electrode 2 T12, a first touch sub-electrode 3 T13 and a first
touch sub-electrode 4 T14.
[0075] The second touch electrode each comprises four second touch
sub-electrodes: a second touch sub-electrode 1 T21, a second touch
sub-electrode 2 T22, a second touch sub-electrode 3 T23 and a
second touch sub-electrode 4 T24.
[0076] The first touch sub-electrode 1 T11 of one of the first
touch electrode takes up a second line and second row sublattice
2L2R, a second line and third row sublattice 2L3R, a third line and
third row sublattice 3L3R as well as a third line and fourth row
sublattice 3L4R of the checkerboard lattice S; the first touch
sub-electrode 2 T12 takes up a fourth line and first row sublattice
4L1R and a fourth line and second row sublattice 4L2R of the
checkerboard lattice S; the first touch sub-electrode 3 T13 takes
up a fifth line and third row sublattice 5L3R and a fifth line and
fourth row sublattice 5L4R of the checkerboard lattice S; the first
touch sub-electrode 4 T14 takes up a sixth line and first row
sublattice 6L1R and a sixth line and second row sublattice 6L2R of
the checkerboard lattice S.
[0077] The second touch sub-electrode 1 T21 of one of the second
touch electrode takes up a first line and third row sublattice 1L3R
of the checkerboard lattice S; the second touch sub-electrode 2 T22
takes up a first line and fifth row sublattice 1L5R, a second line
and fifth row sublattice 2L5R, a third line and fifth row
sublattice 3L5R as well as a third line and sixth row sublattice
3L6R of the checkerboard lattice S; the second touch sub-electrode
3 T23 takes up a second line and seventh row sublattice 2L7R of the
checkerboard lattice S; the second touch sub-electrode 4 T24 takes
up a fourth line and third row sublattice 4L3R and a fourth line
and fourth row sublattice 4L4R of the checkerboard lattice S;
[0078] The two first touch electrodes are centrally symmetrical
with respect to a central point O of the checkerboard lattice
S;
[0079] The two second touch electrodes are centrally symmetrical
with respect to the central point O of the checkerboard lattice
S;
[0080] The line direction of the checkerboard lattice S is the
first direction, and the row direction of the checkerboard lattice
S is the second direction.
[0081] It should be noted that the checkerboard lattice in the
embodiment is a imaginary checkerboard lattice only for the purpose
of describing the structure of the touch electrode assembly 500,
and does not actually exist.
[0082] The touch electrode assembly 500 comprises two first touch
electrodes 501 and two second touch electrodes 502. The two first
touch electrodes 501 are insulated from each other, and the two
second touch electrodes 502 are insulated from each other, and any
first touch electrode and any second touch electrode are insulated
from each other, i.e., one touch electrode assembly comprises four
touch electrodes insulated from each other. The first touch
electrode has a plurality of first effective widths in the second
direction, the first effective widths are the widths of the first
touch electrode along the first direction; the ratio of any two
first effective widths is in the range of 0.9-1.12. The second
touch electrode has a plurality of second effective widths along
the first direction, the second effective widths are the widths of
the second touch electrode along the first direction; the ratio of
any two second effective widths is in the range of 0.9-1.12; the
ratio of the effective widths of any first touch electrode and the
effective widths of any second touch electrode is in the range of
0.9-1.12; the definitions of the first effective widths and the
second effective widths are identical with those of the previous
embodiment. FIG. 5a shows two first effective widths D11 and D12,
and two second effective widths D21 and D22, where
D21=D21a+D21b.
[0083] According to the graphic structure of a touch electrode
according to the embodiment, the effective widths of each
electrically independent touch electrode along the first direction
have little difference, so that influences of display signals on
the each touch electrode are basically consistent when an image is
displayed by each touch electrode, therefore the issue that
graphics of mutually fit touch electrode assemblies are visible
when being displayed is solved; moreover, the graphic structure of
the touch electrode provided by the embodiment can enable each
touch electrode assembly has more uniform distribution due to the
mutually fit of each touch electrode assembly. Thus, the each touch
electrode assembly has a larger capacitive effective area, the
touch precision and sensitivity can be enhanced, and pen touch can
be supported better.
[0084] Alternatively, two second touch electrodes can be
electrically connected. Two second touch electrodes in the
embodiment can be an integrated structure, and are combined into a
touch electrode. At the same time, any two second effective widths
of the touch electrode in the second direction still meet the
condition that the ratio is in the range of 0.9-1.12. The
integrated structure simplifies the track design, and lowers the
technological difficulty of manufacturing the touch electrode.
[0085] Alternatively, each sublattice of the checkerboard lattice
is a square with the equal side length. It should be understood
that when each sublattice of the checkerboard lattice is a square
with the equal side length, each first touch sub-electrode and each
second touch sub-electrode can be regarded as irregular graphics.
Thus the design is beneficial to the tight arrangement of the touch
electrode assemblies, thereby increasing the effective area of a
capacitor, and enhancing the touch sensitivity.
[0086] Continue to refer to FIG. 6, FIG. 6 is a schematic diagram
of mutually concave-convex fit of a plurality of touch electrode
assemblies according to the embodiment. As shown in FIG. 6, one
touch electrode assembly 400 and four adjacent touch electrode
assemblies 400a, 400b, 400c and 400d are fit together in a
concave-convex fit mode described in FIG. 1c. Compared with the
graphic structure of the touch electrode in the previous
embodiment, an electrical connection structure of each first touch
sub-electrode and each second touch sub-electrode in one touch
electrode assembly is simpler. It can be seen easily from FIG. 6
that the graphic structure of the touch electrode assembly in the
embodiment and the one in the previous embodiment have the
advantage of tight arrangement, and each touch electrode assembly
has the necessary insulation distance, besides also has the largest
touch electrode area, thereby further enhancing the touch
sensitivity.
[0087] Further another embodiment provides a touch display panel
comprising a graphic structure of the touch electrode as the
graphic structure in the previous embodiments. The graphic
structure in the previous embodiments will not be described in
detail. The embodiment is characterized in that the touch display
panel comprises a plurality of gate lines for transmitting drive
scanning signals of a film transistor. The first direction is the
same as a extension direction of the gate lines, and the second
direction is perpendicular to the first direction.
[0088] Alternatively, the touch electrode assemblies act as touch
electrodes at the touch phase, and act as common electrodes at the
display phase, where the common electrodes provide common signals
for display pixels.
[0089] The touch display panel generally comprises a plurality of
display pixels, where each display pixel comprises a film
transistor, a pixel electrode and a common electrode. A drain
electrode of the film transistor is electrically connected with the
pixel electrode. A source electrode of the film transistor is
electrically connected with a data line. A gate electrode of the
film transistor is electrically connected with one end of a gate
line, and the other end of the gate line is connected with a gate
driving circuit. When an image is displayed, the gate driving
circuit can send a drive scanning signal, and the connection and
disconnection of the film transistor are controlled by the gate
line. When the film transistor is connected, a display signal is
input into the display pixel via the data line, and is received by
the pixel electrode. Meanwhile, the common electrode receives a
common signal, and an electric field is formed between the pixel
electrode and the common electrode form, thereby controlling the
display panel to display images. In the embodiment, the touch
electrode assembly acts as the common electrode at the display
phase. At the touch phase, the touch electrode assembly receives a
touch signal as a touch electrode, and by the multiplexing of the
common electrode and the touch electrode, the manufacturing working
procedure of the integrated touch display panel can be reduced, so
that the manufacturing time can be shortened, and the manufacturing
cost can be lowered.
[0090] The gate driving circuit opens each gate line in the form of
line and line, and the display signal is input to the display pixel
via the data line, and the process disturbs the common electrode to
a certain extent, and the degree of disturbance is relevant to the
width of the common electrode in the gate line direction. The first
direction set in the embodiment is consistent with the extension
direction of the gate lines, i.e., the first effective widths of
the first touch electrode and the second effective widths of the
second touch electrode of the touch electrode assembly are the
widths of the gate lines in the extension direction. Further, the
ratio of any two first effective widths, the ratio of any two
second effective widths as well as the ratio of any first effective
width and any second effective width are in the range of 0.9-1.12.
By the above setting, the disturbance effects to the common
electrodes by display signals are the same, so that the image can
be displayed uniformly without the issue of the graphic visibility
of the touch electrode assembly. According to the touch display
panel provided by the embodiment, on the one hand, since the first
touch electrode and the second touch electrode of the touch
electrode assembly have approximate effective widths in the
direction of the gate lines, the touch display panel has a good
display effect, and on the other hand, because of the mutually fit
between the touch electrode assemblies, the touch display panel has
very high touch sensitivity, and can support the pen touch mode of
1.0-2.5 mm, so that a user has a better touch experience.
[0091] FIG. 7a is a schematic diagram of a touch display panel
according to the embodiment. FIG. 7b is a sectional diagram taken
along AA' in FIG. 7a.
[0092] As shown in FIG. 7a and FIG. 7b, the touch display panel 700
comprises an insulation layer 703 positioned at one side of a
plurality of touch electrode assemblies 701, and a touch metal
layer, the insulation layer 703 is positioned between the touch
metal layer and the touch electrode assembly 701.
[0093] The touch metal layer comprises a plurality of touch signal
lines TSL; a first touch electrode is electrically connected with
at least one touch signal line TSL; each second touch electrode is
electrically connected with at least one touch signal line TSL; the
touch signal lines are used for transmitting touch signals to the
first touch electrode and the second touch electrode.
[0094] Alternatively, the touch electrode assembly 701 in the
embodiment can act as a self-capacitive touch electrode.
[0095] As one of the touch modes, the principle of the
self-capacitive touch function is that, a touch circuit inputs a
touch driving signal to the self-capacitive touch electrode, and
meanwhile the touch electrode outputs a touch detection signal.
When the touch display panel is touched, the capacitance of the
self-capacitive touch electrode to the ground in the vicinity of a
touch point can be changed, so that the touch detection signal
output by the electrode is changed. Each touch electrode
individually represents a coordinate point, and the positions of
touch points can be defined after the touch detection signals of
all the touch electrodes have been processed. In FIG. 7a, each
first touch electrode 701a and each second touch electrode 701b are
both electrically connected with a touch signal line TSL; the touch
circuit 702 transmits the touch driving signals to the first touch
electrode 701a and the second touch electrode 701b via the touch
signal lines TSL, and the first touch electrode 701a and the second
touch electrode 701b return the touch detection signals to the
touch circuit via the touch signal lines TSL.
[0096] As shown in FIG. 7b, the insulation layer 703 has a
plurality of through holes H, the touch signal lines TSL are
electrically connected with the first touch electrode 701a via the
through holes H, and the touch signal lines TSL are electrically
connected with the second touch electrode 701b via the through
holes H.
[0097] According to the touch display panel according to the
embodiment, on the one hand, each touch electrode assembly, which
is the self-capacitive touch electrode, can be fit with each other.
In touch operation, the touch region per unit area can accommodate
more self-capacitive touch electrodes, and moreover, the plurality
of touch electrode assemblies can be fit tightly by the arrangement
of the graphic structure of the specific touch electrode, so that
the touch electrode assembly has the largest electrode area, and
the touch display panel has very high sensitivity; on the other
hand, the differences of effective widths of the first touch
electrode and the second touch electrode of each touch electrode
assembly along the first direction are very small. Therefore, the
graphics of the touch electrode assembly cannot be visible when
being displayed under the condition of keeping the high sensitivity
of the touch display panel, therefore, the touch display panel has
a better display effect.
[0098] Alternatively, FIG. 8a is a schematic diagram of a
connection of a touch electrode assembly according to the
embodiment. FIG. 8b is a sectional diagram taken along CC' in FIG.
8a.
[0099] Referring to FIG. 8a, the touch metal layer also comprises
touch electrode connection lines TCL. The touch electrode
connection lines TCL is used for electrically connecting a
plurality of first touch sub-electrodes of the first touch
electrode and electrically connecting a plurality of second touch
sub-electrodes of the second touch electrode.
[0100] The touch electrode connection lines are used for
electrically connecting the plurality of first touch sub-electrodes
of the first touch electrode, and electrically connecting the
plurality of second touch sub-electrodes of the second touch
electrode through a plurality of through holes of the insulation
layer.
[0101] In order to better describe the connection mode of each
first touch sub-electrode and each second touch sub-electrode of
adjacent touch electrode assemblies, the first touch sub-electrode
3 T13 and first touch sub-electrode 4 T14 are electrically
connected by touch electrode connection lines TCL, and keep the
insulation with the second touch electrode.
[0102] The touch electrode connection lines TCL can be arranged at
the same layer together with the touch signal lines for
transmitting touch signal to the first touch electrode and the
second touch electrode. The connection mode is free and simple, and
the technological manufacturing is simplified.
[0103] Alternatively, FIG. 9a is a schematic diagram of a
connection of two touch electrode assemblies at the mutually fit
part according to the embodiment. FIG. 9b is a partially amplified
schematic diagram at the part C of FIG. 9a. FIG. 9c is a sectional
diagram at part DD' of FIG. 9b. FIG. 9d is a sectional diagram at
part EE' of FIG. 9b. As shown in FIG. 9a-9d, a plurality of first
touch sub-electrodes of the first touch electrode are electrically
connected by common electrodes 905; and/or
[0104] A plurality of second touch sub-electrodes of the second
touch electrode are electrically connected by common electrodes
905.
[0105] The embodiment shows the first mutually fit mode between the
adjacent electrode assemblies, namely, the electrical connection
mode among a plurality of first touch sub-electrodes of the first
touch electrode and the electrical connection mode among a
plurality of second touch sub-electrodes of the second touch
electrode when the adjacent electrode assemblies are in mutual
encircling and fitting mode. In order to describe the connection
mode of the adjacent touch electrode assemblies better in the
mutually fit part, FIG. 9a only shows a first touch electrode of
one touch electrode assembly and a second touch electrode of the
other touch electrode assembly. At the mutually fit part, two touch
sub-electrodes T12 and T11 of the first touch electrode are
electrically connected by common electrodes 905, the second touch
sub-electrodes 1 T21 and second touch sub-electrodes 2 T22 of the
second touch electrode encircled in the first touch electrode 901
are electrically connected by touch connection lines TCL,
insulation layers 903 are formed between the touch connection lines
TCL and the common electrodes 905. The mutual combined connection
mode between the touch connection lines TCL and the common
electrodes guarantees the insulation relationship between the first
touch electrode 901 and the second touch electrode 902, and make
the arrangement more free between the first touch sub-electrodes
and the second touch sub-electrodes.
[0106] It should be noted that the embodiment provides a connection
mode among touch electrode assemblies in the first mutually fit
mode. Regarding to the second mutually fit mode, the adjacent touch
electrode assemblies which are fit in a concave-convex mode can be
connected by the touch connection lines, so that the technological
manufacturing is simpler.
[0107] Alternatively, the embodiment also provides a touch display
device. According to any of the above touch display panel, the
touch display device can be a cell phone, a desktop computer, a
laptop, a tablet personal computer, an electronic photo and the
like. The touch display device provided by the embodiment has high
touch sensitivity and good display effect.
[0108] It should be noted that merely preferred embodiments and the
applied technical scheme of the present disclosure are described
above, and a person skilled in the art should know that the present
disclosure is not limited to the preferred embodiments. Various
obvious variations, readjustment and substitutions can be made by
those skilled person in the art may without departing from the
protection scope of the present disclosure. Therefore, the present
disclosure is described in detail by the embodiments, but the
present disclosure is not limited thereto, and also can include
more other equivalent embodiments without departing from the
concept of the disclosure, and the scope of the present disclosure
is determined by the scope of the attached claims.
* * * * *